Brodeau, L., Barnier, B., Treguier, A., Penduff, T., and Gulev, S.: An
ERA40-based atmospheric forcing for global ocean circulation models, Ocean
Model., 31, 88–104, 2010. a
Chanut, J., Barnier, B., Large, W., Debreu, L., Penduff, T., Molines, J., and
Mathiot, P.: Mesoscale eddies in the Labrador Sea and their contribution to
convection and restratification, J. Phys. Oceanogr., 38, 1617–1643, 2008.
a,
b,
c,
d,
e
Cooke, M., Demirov, E., and Zhu, J.: A model study of the relationship between
sea-ice variability and surface and intermediate water mass properties in the
Labrador Sea, Atmosphere Ocean, 52, 142–154, 2014.
a,
b
Courtois, P., Hu, X., Pennelly, C., Spence, P., and Myers, P.: Mixed layer
depth calculation in deep convection regions in ocean numerical models, Ocean
Model., 120, 60–78, 2017. a
Curry, B., Lee, C., Petrie, B., Moritz, R., and Kwok, R.: Multiyear volume,
liquid freshwater, and sea ice transports through Davis Strait, J. Phys.
Oceanogr., 44, 1244–1266, 2014. a
Dia, A. and Trenberth, K.: Estimates of freshwater discharge from continents:
Latitudinal and seasonal variations, J. Hydrometeor., 3, 660–687, 2002. a
Dickson, R., Meincke, J., Malmberg, S., and Lee, A. J.: The Great Salinity
Anomaly in the Northern North Atlantic 1968–1982, Progr. Oceanogr., 20,
103–151, 1988. a
Dukhovskoy, D., Myers, P., Platov, G., Timmerman, M.-L., Curry, B., Bamber,
J. L., Chassignet, E., Hu, X., Lee, C., and Somaville, R.: Greenland
freshwater pathways in the sub-Arctic Seas from model experiments with
passive tracers, J. Geophys. Res., 121, 877–907, 2015. a
Dussin, R., Barnier, B., and Brodeau, L.: The making of Drakkar forcing set
DFS5, DRAKKAR/MyOcean Rep. 05-10-14, LGGE, Grenoble, France, 2014. a
Eden, C. and Böning, C.: Sources of Eddy Kinetic Energy in the Labrador
Sea, J. Phys. Oceanogr., 32, 3346–3363, 2002. a
Gelderloos, R., Straneo, F., and Katsman, C.: The Mechanism behind the
temporary shutdown of deep convection in the Labrador Sea: Lessons from the
Great Salinity Anomaly Year 1968–71, J. Climate, 25, 6743–6755, 2012.
a,
b,
c,
d,
e
Häkkinen, S.: A simulation of thermohaline effects of a Great Salinity
Anomaly, J. Climate, 12, 1781–1795, 1999.
a,
b
Han, G., Lu, Z., Wang, Z., Helbig, J., Chen, N., and de Young, B.: Seasonal
variability of the Labrador Current and shelf circulation of Newfoundland, J.
Geophys. Res., 113, C12012,
https://doi.org/10.1029/2009JC006091, 2008.
a
Hátún, H., Eriksen, C., and Rhines, P. B.: Buoyant eddies entering the
Labrador Sea observed with gliders and altimetry, J. Phys. Oceanogr., 37,
2838–2854, 2007.
a,
b
Jahn, A. and Holland, M.: Implications of Arctic sea ice changes for North
Atlantic deep convection and the meridional overturning circulation in
CCSM4-CMIP5 simulations, Geophys. Res. Lett., 40, 1206–1211, 2013. a
Jong, M. D., Bower, A., and Furey, H.: Two years of observations of warm-core
anticyclones in the Labrador Sea and their seasonal cycle in heat and salt
stratification, J. Phys. Oceanogr., 44, 427–444, 2014. a
Jourdan, D., Balopoulos, E., Garcia-Fernandez, M., and Maillard, C.: Objective
analysis of temperature and salinity historical data set over the
mediterranean basin, Oceans'98, 1, 82–87, 1998. a
Katsman, C., Spall, M., and Pickart, P.: Boundary current eddies and their role
in the restratification of the Labrador Sea, J. Phys. Oceanogr., 34,
1967–1983, 2004.
a,
b,
c
Kawasaki, T. and Hasumi, H.: Effect of freshwater from the West Greenland
Current on the winter deep convection in the Labrador Sea, Ocean Model.,
75, 51–64, 2014. a
Large, W. and Pond, S.: Open Ocean Momentum Flux Measurements in Moderate to
Strong Winds, J. Phys. Oceanogr., 11, 324–336, 1980. a
Large, W. and Yeager, S.: Diurnal to decadal global forcing for ocean and
sea-ice models: The data set and flux climatologies, NCAR Technical Note,
National Center for Atmospheric Research, 11, 324–336, 2004. a
Lazier, J.: The renewal of Labrador Sea Water, Deep-Sea Res., 20, 341–353,
1973. a
LeBlond, P.: Satellite observations of the Labrador Current undulations,
Atmosphere Ocean, 20, 129–142, 1982. a
Lilly, J., Rhines, P., Schott, F., Lavender, K., Lazier, J., Send, U., and
D'Asaro, E.: Observations of the Labrador Sea eddy field, Progr. Oceanogr.,
59, 75–176, 2003.
a,
b,
c,
d,
e,
f,
g,
h
Luo, H., Castelao, R., Rennermalm, A. K., Tedesco, M., Bracco, A., Yager, P.,
and Mote, T. L.: Oceanic transport of surface meltwater from the southern
Greenland ice sheet, Nature, 9, 528–533, 2016.
a,
b,
c
Madec G. and the NEMO team: Note du Pole de modelisation de l'Institut
Pierre-Simon Laplace No 27,
https://www.nemo-ocean.eu/wp-content/uploads/NEMO_book.pdf, last
access: October 2018, 2016.
a,
b,
c
Manabe, S. and Stouffer, R.: Simulation of abrupt climate change induced by
freshwater input to the North Atlantic Ocean, Lett. Nature, 378, 165–167,
1995. a
Marzocchi, A., Hirschi, J.-M., Holiday, N., Cunningham, S., Blaker, A., and
Coward, A.: The North Atlantic subpolar circulation in an eddy-resolving
global ocean model, J. Mar. Sys., 142, 126–143, 2015. a
McGeehan, T. and Maslowski, W.: Impact of shelf-basin freshwater transport on
deep convection in the western Labrador Sea, J. Phys. Oceanogr., 41,
https://doi.org/10.1175/JPO-D-11-01.1, 2011.
a
Moat, B., Josey, S., Sinha, B., Blaker, A., Smeed, D., McCarthy, G., Johns, W.,
Hirshi, J.-M., Frajka-Williams, E., Rayner, D., Ducjez, A., and Coward, A.:
Major variations in subtropical North Atlantic heat transport at short (5 day)
timescales and their causes, J. Geophys. Res., 121, 3237–3249, 2016.
a,
b
Pickart, R. and Smethie, W.: Temporal evolution of the deep western boundary
current where it enters the sub-tropical domain: Evidence from tracer data,
Deep-Sea Res., 45, 1053–1083, 1998. a
Pickart, R., Torres, D., and Clarke, R.: Hydrography of the Labrador Sea during
Active Convection, J. Phys. Oceanogr., 32, 428–457, 2002.
a,
b
Rhein, M., Fischer, J., Smethie, W., Smythe-Wright, D., Weiss, R., Mertens, C.,
Min, D.-H., Fleischmann, U., and Putzka, A.: Labrador Sea Water: Pathways,
CFC inventory and formation rates, J. Phys. Oceanogr., 32, 648–665, 2002. a
Robson, J., Hodson, D., Hawkins, E., and Sutton, R.: Atlantic overturning in
decline?, Nature, 7, 2–3, 2014.
a,
b,
c
Schmidt, S. and Send, U.: Origin and composition of seasonal Labrador Sea
freshwater, J. Phys. Oceanogr., 37, 1445–1454, 2007.
a,
b,
c
Schulze, L., Pickart, R., and Moore, G.: Atmospheric forcing during active
convection in the Labrador Sea and its impact on mixed layer depth, J.
Geophys. Res., 121, 6978–6992, 2016.
a,
b
Straneo, F.: Heat and Freshwater Transport through the Central Labrador Sea, J.
Phys. Oceanogr., 36, 606–628, 2001.
a,
b,
c,
d,
e
Timmerman, A., Goossee, H., Madec, G., Fichefet, T., Ethe, C., and Dulire, V.:
On the representation of high latitude processes in the ORCA-LIM global
coupled sea-ice ocean model, Ocean Model., 8, 175–201, 2005. a
Våge, K., Pickart, R., Thierry, V., Reverdin, G., Lee, C., Petrie, B.,
Agnew, T., Wong, A., and Ribergaard, M.: Surprising return of deep convection
to the subpolar North Atlantic Ocean in winter 2007–2008, Nature, 2, 67–72,
2008.
a,
b
Yashayaev, I.: Hydrographic changes in the Labrador Sea, 1960–2005, Progr.
Oceanogr., 99, 242–276, 2007. a